Seat support element, seat and associated manufacturing method

ABSTRACT

A support element for a seat includes a body and a covering covering at least a portion of the body, the covering being made of a covering material. The body includes at least one portion having a plurality of discrete structural elements and a plurality of bonding fibers, the bonding fibers having a central core and a sheath covering the core, the sheath being made of a material that melts when subjected to a melting temperature, the body being overmolded onto at least a portion of the covering.

TECHNICAL FIELD

The present invention relates to a support element for a seat of a vehicle, comprising a body and a covering covering at least a portion of the body, the covering being made of a covering material.

The body is intended to support a seat user, for example.

BACKGROUND

It is known from the state of the art that seat support elements have a body made from raw materials, for example, from natural resources. For example, the body is made of organic, mineral or synthetic materials.

For example, the body is produced by expansion molding of a foam precursor material such as thermosetting foam, into a mold cavity having the shape of the body to be produced. To reinforce the body, it is also known to add reinforcing fibers, such as glass fibers, to the foam forming the body.

However, it is then complex to ensure a good cohesion of the body while modulating the reinforcement with precision.

Furthermore, in such a support element, the assembly of the body and the covering is complicated.

SUMMARY

One object of the invention is to overcome these drawbacks by providing a seat support element whose cohesion is ensured in a simple manner, whose body reinforcement is better controlled and whose manufacture is simple.

To this end, the invention relates to a support element for a seat of a vehicle of the aforementioned type, the body comprising at least one portion comprising a plurality of discrete structural elements and a plurality of bonding fibers, the bonding fibers comprising a central core and a sheath covering the core, the sheath being made of a material that melts when subjected to a melting temperature, the body being overmolded onto at least a portion of the covering.

The use of discrete structural elements to form the body of the support element makes it possible to avoid the need for the conventional casting of a foam precursor material into a mold cavity. The mixing of the discrete structural elements and the bonding fibers is easier and allows for simpler and more precise modulation of the body reinforcement while ensuring good cohesion of the body.

In addition, the discrete structural elements can be sourced from a variety of sources, which increases the options for manufacturing the support element. For example, this avoids the use of a foam precursor material derived from natural resources.

Because the body is overmolded onto the covering, the bonding between the body and the covering is simplified. In particular, the number of components of the support element is reduced. Indeed, it is not necessary to resort to additional elements to secure the covering and the body together.

According to other optional features of the invention, taken alone or in any technically conceivable combination:

-   -   the discrete structural elements are formed by a structural         material made of foam and/or structural fibers and/or textile;     -   the structural fibers are formed by a bare core, the bare core         not melting when subjected to the melting temperature;     -   the bonding fibers and/or structural fibers are thermoplastic         fibers, in particular fibers made of polyethylene;     -   the bonding fibers and/or the structural fibers are         thermoplastic fibers, in particular fibers made of polyethylene         terephthalate;     -   the structural material, the covering material and the bonding         fibers are formed by at least one compound in common;     -   the compound in common is polyethylene;     -   the compound in common is polyethylene terephthalate;     -   the structural material and the bonding fibers are composed         solely of the compound in common;     -   the discrete structural elements are formed by the structural         material that is cut and crushed;     -   the discrete structural elements are joined together via the         bonding fibers to form the body;     -   the sheath comprises at least one securing portion attached to         at least one discrete structural element and/or at least one         other bonding fiber;     -   the support element further comprises a securing layer, the         securing layer extending between the body and the covering, the         securing layer securing the covering to the body;     -   the support element further comprises a frame, the body being         connected to the frame, and at least one protective layer for         protecting the body extending between the body and the frame;         and     -   the body defines a bearing surface, the seat support element         further comprising a comfort layer extending over the bearing         surface and being intended to be interposed between a user of         the seat and the bearing surface.

The invention also relates to a vehicle seat of the type comprising a support element as described above, the seat support element being a seat cushion, a backrest or a headrest of the seat.

The invention further relates to a method for manufacturing a seat support element as described above, optionally having one or more of the optional features described above, taken alone or in any technically feasible combination.

According to one embodiment of the method, the seat support element comprises a body and a covering, the covering being made of a covering material, the body comprising at least one portion comprising a plurality of discrete structural elements and a plurality of bonding fibers, the bonding fibers comprising a central core and a sheath covering the core, the sheath being made of a material that melts when subjected to a melting temperature, the method comprising the steps of:

-   -   providing the covering, the discrete structural elements and the         bonding fibers,     -   mixing the discrete structural elements and the bonding fibers         to form a manufacturing assembly and disposing the covering in a         mold for manufacturing the seat support element, and     -   overmolding the body onto at least a portion of the covering in         the mold from the manufacturing assembly,     -   the overmolding step comprising blowing the manufacturing         assembly into the mold onto the covering and a sub-step of         heating the manufacturing assembly and the covering in the mold         to the melting temperature to melt the bonding fiber sheath at         least partially.

According to other optional features of the method, taken alone or in any technically feasible combination:

-   -   the discrete structural elements are formed by a structural         material made of foam and/or structural fibers and/or textile,         wherein the bonding fibers and/or structural fibers are         thermoplastic fibers, in particular fibers made of polyethylene         terephthalate.

BRIEF DESCRIPTION OF THE DRAWINGS

Further aspects and advantages of the invention will become apparent from the following description, given by way of example and made with reference to the appended drawings, in which:

FIG. 1 is a schematic cross-sectional representation of a vehicle seat according to an embodiment of the invention;

FIG. 2 is a simplified schematic representation of the structure made by the discrete structural elements and the bonding fibers of a seat support element according to an embodiment of the invention;

FIG. 3 is a schematic cross-sectional representation of a body and covering of a seat support element according to an embodiment of the invention; and

FIG. 4 is a flow chart of a method for manufacturing a seat support element according to an embodiment of the invention.

DETAILED DESCRIPTION

With reference to FIG. 1, a vehicle seat 10 is described. For example, the seat 10 is a seat of a land, sea or air vehicle. The seat 10 is a seat of a motor vehicle, for example.

The seat 10 is intended to receive a user of the seat 10.

The seat 10 comprises at least one support element 12, intended for supporting the user's body.

The seat 10 comprises a plurality of support elements 12, for example.

The support element 12 forms a seat cushion 14, a backrest 16, or a headrest 18 of the seat 10, for example. It is understood that a single seat 10 may comprise multiple support elements 12.

The support element 12 comprises a frame 22, a body 24 connected to the frame 22, and a covering 27.

The frame 22 constitutes a framework of the support element 12 to which, for example, the body 24 is attached.

The frames 22 of each support element 12 are, connected to each other, for example. The set of frames 22 then constitutes a framework of the seat 10.

The frames 22 are also connected to a (non-illustrated) floor of the vehicle, for example. For example, the frame 22 of the seat 14 is fixed to the floor of the vehicle by means of rails (not illustrated), for example, allowing for adjustment of the position of the seat 10 in the vehicle.

The body 24 of the support element 12 is a support for the user. The user's body is supported on the body 24 when the user uses the seat 10. In particular, the body 24 defines a bearing surface 32. The user is supported by the body 24 at the bearing surface 32.

The body 24 is a molded body. It is attached to the frame 22 by a fastening means.

With reference to FIGS. 1 and 2, the body 24 comprises at least one portion 34 comprising a plurality of discrete structural elements 38 and a plurality of bonding fibers 40.

For example, the discrete structural elements 38 are formed by a structural material made of foam and/or structural fibers and/or textile.

For example, the discrete structural elements 38 are formed by a structural material of a mixture of foam and structural fibers or a mixture of foam and textile or a mixture of structural fibers and textile or a mixture of foam, structural fibers and textile. The discrete structural elements 38 are formed by structural material that is cut and crushed, for example.

For example, the structural material is a material obtained from an object made of foam and/or structural fibers and/or textile. The structural material is then said to be obtained by recycling said object. This reduces the environmental impact of the support element 12 since the structural material is not obtained from raw resources taken from the environment.

In a variant or additionally, the structural material is derived from material discarded during the production of an object made of foam and/or structural fibers and/or textile, for example. The material is then derived from excess material during the manufacture of the object. This also reduces the environmental impact of the support element 12. This is because the use of surplus material reduces the waste of resources. In addition, the use of the surplus contributes to the reduction of carbon dioxide emissions into the atmosphere since incinerating said surplus is thus avoided. Moreover, the use of the surplus contributes to the reduction of soil pollution since it is avoided to bury the said surplus.

The foam of the structural material is a polyurethane (PU) foam, for example. The structural fibers of the structural material are plastic fibers such as polyethylene terephthalate (PET) fibers, for example. The textile of the structural material is a simple textile, for example, also known as a bare textile, such as a non-woven fabric or a complex textile, such as a laminated textile that comprises a textile layer and a foam layer, for example.

As illustrated in FIG. 2, the discrete structural elements 38 are in the form of flakes 42 of material or granules of material in the body 24, for example. Such a flake of material then constitutes a discrete structural element 38 within the meaning of the invention. Such a material flake 42 is formed in particular by foam and/or textile and/or a mixture of foam and textile. The flakes 42 have a dimension of between 5 mm and 50 mm, for example. This dimension is the average diameter of the flake 42, for example, or its dimension along its direction of elongation for an elongated element or other.

As illustrated in FIG. 2, the discrete structural elements 38 are, strands 43, for example. Such a strand 43 then constitutes a discrete structural element 38 within the meaning of the invention. Such a strand 43 is a structural fiber as described above, in particular. The strands 43 have a dimension of between 30 mm and 120 mm, for example. This dimension is the dimension of a strand 43 along its direction of elongation, for example. The strands 43 have a count of between 6 dtex and 17 dtex, for example.

The proportion of discrete structural elements 38 constitutes between 50% and 90% by weight of the portion 34 of the body 24, for example, preferably between 55% and 85% by weight. The proportion of bonding fibers 40 constitutes between 10% and 50% by mass of the portion 34 of the body 24, for example, preferably between 15% and 45% by mass.

According to one embodiment, the proportion of discrete structural elements 38 varies from one part 34 of the body 24 to another.

The discrete structural elements 38 participate in the reinforcing of the body 24. In particular, by varying the proportion of discrete structural elements 38 and, further, by varying the composition of the discrete structural elements 38, the reinforcement of the body 24 can be precisely modulated. “Varying the composition” means varying the composition of the structural material by varying proportions of foam and/or proportions of structural fibers and/or proportions of textile.

As illustrated in FIG. 2, the discrete structural elements 38 are joined together by means of the bonding fibers 40 to form the portion 34 of the body 24.

The bonding fibers 40 are thermoplastic fibers, for example.

The bonding fibers 40 are, dual component fibers, for example. They comprise a central core and a sheath covering the central core. The sheath is made of a material that melts when subjected to a melting temperature.

The bonding fibers 40 are made of at least two polymers having different characteristics, for example. The core is made of a first polymer and the sheath is made of a second polymer, for example. The first and second polymers are the same polymer but with different characteristics (same chemical formula, but different physicochemical characteristics) for example. According to a variant, the first and second polymers are different polymers (different chemical formulas). For example, the first polymer is a polyester and the second polymer is a co-polyester. According to another example, the first polymer is a polyamide and the second polymer is a co-polyamide.

In other words, the second polymer has a melting temperature substantially equal to the melting temperature. The melting temperature is between 70° C. and 200° C., for example.

As illustrated in FIG. 2, the sheath of bonding fibers 40 comprises at least one securing portion 44 attached to at least one discrete structural element 38 and/or at least one other bonding fiber 40.

The bonding fibers 40 are attached to a discrete structural element 38 and/or another bonding fiber 40 via the securing portions 44.

In other words, the bonding fibers 40 act as an adhesive between the discrete structural elements 38. The sheath has melted and re-solidified to ensure the securing with the discrete structural elements 38 and/or the other bonding fibers 40. In particular, the securing portions 44 have melted and resolidified to ensure this securing.

In addition to securing the discrete structural elements 38 together, the bonding fibers 40 reinforce the body 24. They ensure a good cohesion of the part 34 of the body 24 and improve its mechanical properties.

The reinforcement of the body 24 is thus precisely modulated by varying, in addition, the proportions of bonding fibers 40 in relation to the proportion of discrete structural elements 38.

The bonding fibers 40 and/or structural fibers are thermoplastic fibers, for example. According to one example, the bonding fibers 40 and/or the structural fibers are fibers made of polyethylene. In a variant, the bonding fibers 40 and/or the structural fibers are fibers made of polyethylene terephthalate.

Unlike the bonding fibers 40, the structural fibers that make up the strands 43 comprise a core but lack a sheath covering said core. In other words, the structural fibers are formed by a bare core. The bare core does not melt when subjected to the melting temperature.

The portion 34 of the body 24 comprising the discrete structural elements 38 and the bonding fibers 40 is a portion in direct contact with the frame 22, for example. The portion 34 of the body 24 may be overmolded by another portion of the body 24, for example made in a conventional manner, for example, with a conventional thermosetting foam, this conventional foam portion forming at least a portion of the bearing surface 32 of the support element, for example, which a user bears on when sitting in the seat.

With reference to FIGS. 1 and 3, the covering 27 covers at least a portion of the body 24. The covering 27 extends over the body 24 opposite the frame 22, for example.

The covering 27 provides the aesthetic appearance of the support element 12, for example. In addition, the covering 27 constitutes the fastening means, securing the body 24 and the frame 22 together, for example. The covering 27 surrounds the body 24, for example, and surrounds the frame 22 at least partially and secures them together. For example, the covering 27 comprises parts for securing to the frame 22. The securing part are parts made of plastic, for example.

The body 24 is overmolded onto at least a portion of the covering 27. According to a particular embodiment, the body 24 is overmolded on the entire covering 27.

The covering 27 is made of a covering material.

The structural material, the covering material and the bonding fibers 40 are formed by at least one compound in common, for example. The compound in common is polyethylene, for example. According to a variant, the compound in common is polyethylene terephthalate.

According to one particular embodiment, the structural material and the bonding fibers 40 are solely composed of the compound in common.

The presence of common compounds in the structural material, covering material and/or bonding fibers 40 facilitates recycling of the support element 12.

The support element 12 further comprises a securing layer (not shown), for example. The securing layer extends between the body 24 and the covering 27, for example. The securing layer secures the body 24 and the covering 27 together. For example, the securing layer is a thermally activated securing layer. In other words, the securing layer permanently attaches the body 24 and the covering 27 when the temperature of the securing layer reaches an activation temperature. The activation temperature is between 70° C. and 200° C., for example. Advantageously, the activation temperature is substantially equal to the melting temperature.

With reference to FIG. 1, only the backrest 16 comprises a covering 27. According to another example, the seat cushion 14 and/or the headrest 18 comprise a covering 27.

According to one embodiment, the support element 12 comprises a protective layer 26 extending between the body 24 and the frame 22. With reference to FIG. 1, only the backrest 16 comprises a protective layer 26. According to another example, the seat cushion 14 also comprises a protective layer 26.

For example, the protective layer 26 is formed by a textile such as a non-woven fabric. According to a variant, the protective layer 26 comprises discrete structural elements 38 and bonding fibers 40, like the portion 34 of the body 24.

The protective layer 26 is attached to the body 24. For example, the protective layer 26 is glued to the body 24.

The protective layer 26 protects the body 24 from abrasion due to contact with the frame 22. In other words, the protective layer 26 reduces wear on the body 24 over time. In addition, the protective layer 26 reduces the noise generated by the body 24 rubbing against the frame 22. The protective layer 26 is attached to the frame 22 by the fastening means attaching the frame 22 and the body 24.

According to one embodiment that can be combined with the embodiment in which the support element 12 comprises a protective layer 26, the support element 12 further comprises a comfort layer 28 extending over at least a portion of the bearing surface 32 between the body 24 and the covering 27. The comfort layer 28 is intended to be interposed between the user of the seat 10 and the bearing surface 32. In other words, the comfort layer 28 covers the body 24 at least over a portion of the bearing surface 32 thereof. The comfort layer 28 ensures the approach comfort and contact comfort of the support element 12. In particular, the comfort layer 28 determines the sensation upon touching of the user of the seat 10 when the user uses the seat 10.

The securing layer further extends between the body 24 and the comfort layer 28, for example. The securing layer further secures the body 24 and the comfort layer 28.

With reference to FIG. 1, only the backrest 16 comprises a comfort layer 28. According to another example, the seat cushion 14 and/or the headrest 18 comprise a comfort layer 28.

The comfort layer 28 extends over at least a portion of the body 24.

The comfort layer 28 is bonded to the covering 27. It is made of discrete structural elements 38 and bonding fibers 40 and/or a textile, for example, consisting of PET with comfort-enabling mechanical properties and/or PU foam and/or structural fibers, for example.

When the comfort layer 28 is made of the same material as the body 24, this facilitates recycling of the support element 12.

The body 24 is further overmolded onto the comfort layer 28, for example.

According to one particular example, the discrete structural elements 38 are formed by a PET structure fibers material only, the bonding fibers 40 are formed by PET for the first polymer and co-polyethylene terephthalate (coPET) for the second polymer. If applicable, the covering 27 is made of PET. If applicable, the comfort layer 28 is made of PET. In this way, all of the elements constituting the support element comprise PET. The potential recycling of the support element 12 is thus facilitated. One can indeed envisage chemical recycling, mechanical recycling (fraying and/or crushing) and/or thermomechanical recycling (melting) of the support element 12.

In the following, with reference to FIG. 4, a method 100 for manufacturing a support element 12 as described above is described, according to the various embodiments, examples of realization and variants.

In a first step 110, a plurality of discrete structural elements 38, a plurality of bonding fibers 40, and a covering 27 are provided.

This first step 110 comprises cutting and crushing the structural material, for example. In particular, it involves cutting and crushing a seat support element considered to be waste, for example. According to another example or additionally, it involves cutting and crushing waste material during the production of an object.

In a second step 120, the discrete structural elements 38 and the bonding fibers 40 are mixed to form a manufacturing assembly.

The covering 27 is disposed in a manufacturing mold of the support element 12. If desired, the comfort layer 28 is glued to the coating 27.

The method 100 then comprises a third step 130 of overmolding the body 24 onto the covering 27 and onto the comfort layer 28, if applicable. This step corresponds to shaping the manufacturing assembly so that it acquires the shape of at least the portion 34 of the body 24. The manufacturing assembly is blown into the mold over the covering 27 and over the comfort layer 28, if applicable, so that the body 24 is overmolded onto the covering 27.

Overmolding the body 24 onto the covering 27 comprises placing the manufacturing assembly in a mold cavity of the mold. The mold cavity of the mold has the shape of the portion 34 of the body 24 to be made. The arrangement of the manufacturing assembly is performed by blowing the manufacturing assembly into the mold, for example. Placing the manufacturing assembly in the mold is, followed by blowing air into the mold, for example, to disperse and mix the manufacturing assembly in the mold.

During the overmolding step, a bonding of the discrete structural elements 38 to each other occurs via the bonding fibers 40.

The overmolding step comprises a fourth step 140, a fifth step 150 and a sixth step 160. The fourth, fifth and sixth steps 140, 150, 160 are sub-steps of the overmolding step.

In the fourth step 140, the manufacturing assembly 140 and the covering 27 are pressed into the mold.

In the fifth step 150, the manufacturing assembly and the covering 27 are heated in the mold at the melting temperature to melt the bonding fibers 40 at least partially, in particular to melt the sheath of the bonding fibers 40 at least partially. In particular, the securing portions 44 of the bonding fibers 40 between said fibers and discrete structural elements 38 and/or other fibers melt at least partially, to provide securing between the bonding fibers 40 and the discrete structural elements 38. The securing layer is then thermally activated and the securing layer secures the body 24 and the covering 27 together. If necessary, the securing layer also secures the body 24 and the comfort layer 28.

In the sixth step 160, the manufacturing assembly and the covering 27 are cooled so that the discrete structural elements 38 are bonded together via the bonding fibers 40. The previously melted sheath solidifies again to ensure the securing of the discrete structural elements 38 and/or the other bonding fibers 40 together. In particular, the previously melted securing portions 44 solidify again to provide this securing. The securing portions 44 thus constitute portions where the bonding fibers 40 and the discrete structural elements 38 are attached.

Following the sixth step 160, the remainder of the body 24 is overmolded onto the portion 34, for example.

The mold is then opened and the assembly comprising the body 24 and the covering 27 is demolded.

If necessary, the protective layer 26 is then glued to the body 24.

The assembly comprising the body 24, the covering 27 and, if applicable, the protective layer 26 and the comfort layer 28 are then attached to the frame 22 so that the protective layer 26 extends between the body 24 and the frame 22.

According to a variant, the body 24 is formed entirely of discrete structural elements 38 and bonding fibers 40.

According to another variant, the portion of the body 24 in contact with the covering 27 and, if applicable, the comfort layer 28 is formed of discrete structural elements 38 and bonding fibers 40. Said portion of the body 24 is the portion 34 of the body 24, comprising the discrete structural elements 38 and the bonding fibers 40, for example. According to this variant, the body 24 is fixed with the covering 27, and if applicable with the comfort layer 28, via the bonding fibers 40. The bonding fibers 40 thus enable the body 24 to be securely attached to the covering 27, and if applicable to the comfort layer 28. When the support element 12 comprises the securing layer, the bonding fibers 40 bind, the body 24 and the securing layer, for example. Thus, the securing of the body 24 to the covering 27, and to the comfort layer 28, if applicable, is accomplished during the mold heating step followed by the mold cooling step. The securing portions 44 melt and re-solidify to ensure the securing of the discrete structural elements 38 to the covering 27 and the comfort layer 28, if applicable.

According to yet another variant, a portion of the body 24 different from the portion 34 may be made of thermosetting foam, for example, following a conventional molding of thermosetting foam precursor material. The thermosetting foam is PU foam, for example. Advantageously, this foam part is overmolded on the portion 34.

According to yet another variant, the support element 12 further comprises a thermo-bonding layer, connected to the protective layer 26. The thermo-bonding layer is a heat-activated securing layer. The thermo-bonding layer ensures the securing between the protective layer 26 and the body 24. During the manufacturing method, the protective layer 26 is then applied to the manufacturing assembly in the mold after the manufacturing assembly is blown. The thermo-bonding layer is then activated by heat activation, particularly during the heating step of the manufacturing method for the support element 12. The thermo-bonding layer then attaches together the protective layer 26 and the body 24.

According to another variant, the comfort layer 28 is made of a textile. During the manufacturing method, the comfort layer 28 is then woven onto the covering 27.

According to another variant, the comfort layer 28 is mechanically attached to the covering 27 with a plastic clip, hook, or hanging loops, for example.

According to another variant, the comfort layer 28 is glued to the covering 27. For example, the comfort layer 28 is glued to the covering 27 by means of a thermally activated securing layer. The bonding is, performed during the heating step of the method for manufacturing the support element 12, for example.

The seat support element 10 allows for effective body cohesion while providing accurate modulation of the body reinforcement 24.

In addition, the bonding between the body 24 and the covering 27 is simplified since the body 24 is overmolded onto the covering 27. This reduces the number of components required to make the support element 12.

Finally, the seat support element 10 has a reduced environmental impact. The use of discrete structural elements 38 bonded together by bonding fibers 40 to make the body 24 offers alternatives to conventional molding from raw thermoset foam. 

1. A support element for a seat of a vehicle, comprising a body and a covering covering at least a portion of the body, the covering being made of a covering material, wherein the body comprises at least one portion comprising a plurality of discrete structural elements and a plurality of bonding fibers, the bonding fibers comprising a central core and a sheath covering the core, the sheath being made of a material that melts when subjected to a melting temperature, the body being overmolded onto at least a portion of the covering.
 2. The support element according to claim 1, wherein the discrete structural elements are formed by a structural material made of foam and/or structural fibers and/or textile.
 3. The support element according to claim 2, wherein the structural fibers are formed by a bare core, the bare core not melting when subjected to the melting temperature.
 4. The support element according to claim 2, wherein the bonding fibers and/or structural fibers are thermoplastic fibers.
 5. The support element according to claim 4, wherein the bonding fibers and/or the structural fibers are fibers made of polyethylene.
 6. The support element according to claim 2, wherein the structural material, the covering material and the bonding fibers are formed by at least one compound in common.
 7. The support element according to claim 6, wherein the structural fibers are formed by a bare core, the bare core not melting when subjected to the melting temperature, the compound in common being polyethylene.
 8. The support element according to claim 6, wherein the structural fibers are formed by a bare core, the bare core not melting when subjected to the melting temperature, the compound in common being polyethylene terephthalate.
 9. The support element according to claim 7, wherein the structural material and the bonding fibers are solely composed of the compound in common.
 10. The support element according to claim 2, wherein the discrete structural elements are formed by the structural material that is cut and crushed.
 11. The support element according to claim 1, wherein the discrete structural elements are joined together via the bonding fibers to form the body.
 12. The support element according to claim 1, wherein the sheath comprises at least one securing portion attached to at least one discrete structural element and/or at least one other bonding fiber.
 13. The support element according to claim 1, further comprising a securing layer, the securing layer extending between the body and the covering, the securing layer securing the covering to the body.
 14. The support element according to claim 1, further comprising a frame, the body being connected to the frame, and at least one protective layer for protecting the body extending between the body and the frame.
 15. The support element according to claim 1, the body defining a bearing surface, the seat support element further comprising a comfort layer extending over the bearing surface and being intended to be interposed between a user of the seat and the bearing surface.
 16. A vehicle seat comprising a support element according to claim 1, the seat support element being a seat cushion, a backrest or a headrest of the seat.
 17. A method for manufacturing a seat support element of a vehicle, the seat support element comprising a body and a covering, the covering being made of a covering material, the body comprising at least one portion comprising a plurality of discrete structural elements and a plurality of bonding fibers, the bonding fibers comprising a central core and a sheath covering the core, the sheath being made of a material that melts when subjected to a melting temperature, the method comprising: providing the covering, the discrete structural elements and the bonding fibers, mixing the discrete structural elements and the bonding fibers to form a manufacturing assembly and disposing the covering in a mold for manufacturing the seat support element, and overmolding the body onto at least a portion of the covering in the mold from the manufacturing assembly, the overmolding comprising blowing the manufacturing assembly into the mold onto the covering and heating the manufacturing assembly and the covering in the mold to the melting temperature to melt the bonding fiber sheath at least partially.
 18. The method according to claim 17, wherein the discrete structural elements are formed by a structural material made of foam and/or structural fibers and/or textile, wherein the bonding fibers and/or structural fibers are thermoplastic fibers.
 19. The support element according to claim 4, wherein the bonding fibers and/or the structural fibers are fibers made of polyethylene terephthalate.
 20. The method according to claim 18, wherein the bonding fibers and/or structural fibers are fibers made of polyethylene terephthalate. 